Evaluation of histochemical observations of activity of acid hydrolases obtained with semipermeable membrane techniques. 3. The substrate specificity of isoenzymes of acid phosphatase in m.gastrocnemius of rabbits.

Three distinct isoenzymes of acid phosphatase have been separated from extracts of m.gastrocnemius of normal and of vitamin E deficient rabbits by gel filtration and polyacrylamide gel electrophoresis. These isoenzymes, termed I, II and III, have molecular weights of: 110,000--130,000, 60,000--78,000 and 12,500--14,500. Isoenzymes I and II split the substrates 4-methylumbelliferyl phosphate and naphthol AS-BI phosphate and the activity is strongly increased in the muscles of vitamin E deficient rabbits. Isoenzyme III splits only 4-methylumbelliferyl phosphate and the activity is not increased in the muscles of vitamin E deficient rabbits. The pH-optimum for isoenzymes I and II is 4.8 and for isoenzyme III 5.5. It has been shown that the histochemical semipermeable membrane technique, using substrate naphthol AS-BI phosphate, is a very reliable technique for demonstrating activity of the isoenzymes I and II in tissue sections. On the other hand, activity of isoenzyme III cannot be demonstrated with this histochemical technique. In pathologically altered muscles, the activity of the isoenzymes I and II is greatly increased whilst the activity of isoenzyme III is not significantly altered.     

Evaluation of histochemical observations of activity of acid hydrolases obtained with semipermeable membrane techniques

Summary Three distinct isoenzymes of acid phosphatase have been separated from extracts of m.gastrocnemius of normal and of vitamin E deficient rabbits by gel filtration and polyacrylamide gel electrophoresis. These isoenzymes, termed I, II and III, have molecular weights of: 110,000–130,000, 60,000–78,000 and 12,500–14,500. Isoenzymes I and II split the substrates 4-methylumbelliferyl phosphate and naphthol AS-BI phosphate and the activity is strongly increased in the muscles of vitamin E deficient rabbits. Isoenzyme III splits only 4-methylumbelliferyl phosphate and the activity is not increased in the muscles of vitamin E deficient rabbits. The pH-optimum for isoenzymes I and II is 4.8 and for isoenzyme III 5.5. It has been shown that the histochemical semipermeable membrane technique, using the substrate naphthol AS-BI phosphate, is a very reliable technique for demonstrating activity of the isoenzymes I and II in tissue sections. On the other hand, activity of isoenzyme III cannot be demonstrated with this histochemical technique. In pathologically altered muscles, the activity of the isoenzymes I and II is greatly increased whilst the activity of isoenzyme III is not significantly altered.This study was supported by a grant from the Prinses Beatrix Fonds, 's Gravenhage, The Netherlands and was partly extracted from the Ph.D. thesis of D.E. Israël (1977)     

The increase in activity of acid hydrolases in muscles of rats after subcutaneous administration of dimethyl-para-phenylene diamine. A combined histochemical and biochemical investigation

Summary The increase in activity of acid hydrolases in skeletal muscles of rats after subcutaneous administration of dimethyl-para-phenylene diamine (DPPD) was studied with a combined histochemical and biochemical investigation. In part I the histochemical findings were presented. In this communication the biochemical findings are reported and compared with the histochemical findings.In homogenates of m. biceps femoris, m. gastrocnemius and m. rectus femoris of DPPD-treated rats, the activity of the lysosomal acid hydrolases, cathepsin D, acid maltase, acid phosphatase, and -glucuronidase was increased. This increase in activity was maximal after 7 to 9 days of DPPD treatment and ran parallel to the severity of the pathological changes. Statistical calculations clearly reveal that the increased activity of one acid hydrolase was significantly paralleled by an increased activity of a second acid hydrolase. Moreover these calculations reveal that the biochemical activity findings correlated with the histochemical activity findings. However it was remarkable that in the histochemical study, the estimated increase in acid phosphatase activity was much more than the increase in acid phosphatase activity found biochemically, whilst on the other hand the histochemically estimated increase in -glucuronidase activity corresponded with the biochemical observations. The results of gel filtration techniques have shown that this discrepancy of acid phosphatase activity was caused by different substrate specificity of the different isoenzymes of acid phosphatase and that as a result of the DPPD treatment the isoenzyme pattern had been altered. The elution patterns showed three distinct isoenzymes of acid phosphatase of normal and of DPPD treated rats. These isoenzymes, termed I, II and III, have molecular weights of: 200,000 or more, 83,500–104,500 and 14,500–18,100. Isoenzymes I and II split the substrates 4-methylumbelliferyl phosphate and naphthol AS-BI phosphate and the activity is strongly increased in the muscles of the DPPD treated rats. Isoenzyme III does not split naphthol AS-BI phosphate and the activity is not increased in the muscles of the DPPD treated rats. Considering the fact that it has been shown that the activity of isoenzyme III is high compared with that of the isoenzymes I and II, it is important to realise that by using naphthol AS-BI phosphate not all acid phosphatase can be demonstrated in sections of skeletal muscle.This study was partly supported by a grant from the Prinses Beatrix Fonds, 's Gravenhage, The Netherlands, and was mainly extracted from the Ph. D. thesis of D.E. Israël (1977).     

Dimeric nature and amino acid compositions of homogeneous canine prostatic human liver and rat liver acid phosphatase isoenzymes. Specificity and pH-dependence of the canine enzyme.

Two isoenzymes of rat liver acid phosphatase (orthophosphoric-monoester phosphohydrolase (acid optimum) EC 3.1.3.2) have been purified to homogeneity, at least one of these for the first time. Both of the rat liver isoenzymes have identical specific activities towards p-nitrophenyl phosphate. Molecular weights of the native enzymes are 92 000 for rat liver isoenzyme I and 93 000 for isoenzyme II, while the subunit molecular weights are 51 000 and 52 000 respectively. Data on substrate specificity and pH dependence are presented for the homogeneous canine prostatic enzyme, which is also isolated as a dimeric enzyme of (native) molecular weight 89 000. Carbohydrate analysis data are presented for canine prostatic acid phosphatase and it is further noted that both isoenzymes of rat liver acid phosphatase are also glycoproteins. The amino acid compositions of the two rat liver isoenzymes are presented together with those of the similar dimeric acid phosphatase of human liver and of canine prostate. Comparison of these results with published data for the amino acid composition of human prostatic acid phosphatase shows substantial similarities. However, significant differences are seen in the amino acid composition of rat liver acid phosphatase isoenzyme I as compared to a previous literature report. Most notably, 17 histidine residues are found per mol of isoenzyme I and 18 for isoenzyme II.     

Different tartrate sensitivity and pH optimum for two isoenzymes of acid phosphatase in osteoclasts. An electron-microscopic enzyme-cytochemical study

Summary By differentiation of substrate specificity, pH optimum range, and sensitivity to various inhibitors, 2 isoenzymes of acid phosphatase in bone cells have been studied at the electron-microscopic level. When p-nitrophenyl phosphate was used for the substrate, the demonstrable enzyme activity was affected by neither tartrate nor sodium fluoride. The reaction product, when incubated at pH 5–6, was detected in all sites along the pathway for the biosynthesis of acid phosphatase in the osteoclast, including the perinuclear space, cisternae of the endoplasmic reticulum, Golgi complex, various vesicles, and vacuoles. In the osteoclasts attached to bone, the enzymatic activity was demonstrated at the extracellular ruffled border and on the eroded bone surface. Reaction products became confined to lysosomes and extracellular ruffled border when incubated at pH 6–7. Unattached osteoclasts showed a similar intracytoplasmic localization of enzyme as the attached ones, except for the absence of the extracellular enzyme activity. The mononuclear, immature type of osteoclast also resembled the mature osteoclast in terms of enzymatic localization. Except for the osteoclasts, the acid p-nitrophenyl phosphatase activity was restricted to lysosomal vesicles in various bone cells, monocytes, and macrophages. Such activity was inhibited by adding 50 mM tartrate to the p-nitrophenyl phosphate medium. When -glycerophosphate or p-nitrocatechol sulfate was the substrate, most of the reaction product was localized intracellularly. Unlike the acid p-nitrophenyl phosphatase, the acid -glycerophosphatase or arylsulfatase activity in osteoclasts and other bone cells was inhibited completely by 10 mM tartrate or 10 mM sodium fluoride. Even preincubation of 100 mM tartrate in the buffer inhibited -glycerophosphatase activity completely, but p-nitrophenyl phosphatase activity was inhibited incompletely. Consequently, our results suggest that acid p-nitrophenyl phosphatase is a useful cytochemical marker for identification of the osteoclast family at electron-microscopic levels of resolution.     

A Quantitative Histochemical Study of Alkaline Phosphatase Activity in Isolated Rat Duodenal Epithelial Cells

A simple separation method enabling the quantification of alkaline phosphatase activity in unfixed, isolated, individual, duodenal epithelial cells has been presented. The activity of intestinal brush border-bound alkaline phosphatase has been demonstrated using naphthol AS-BI phosphate as a substrate and hexazotized New Fuchsin as a simultaneous coupling agent. The amount of final reaction product, as measured cytophotometrically, increases linearly with incubation time (up to 10 min) and with substrate concentration (up to 0.4 mM). Maximum enzyme activity was obtained at pH 8.9. Variation of the substrate concentration revealed the kinetic parameters for naphthol AS-BI phosphate as K_m = 0.17 ± 0.015 and V_max = 13.9 ± 1.38. The specificity of the enzyme reaction was confirmed by the complete inhibition of the enzyme activity in the presence of l-cysteine (10 mm) and 80% inhibition with L - phenylalanine (30 mM). Comparison of alkaline phosphatase activity in 8-m cryostat sections (beginning at the tip and proceeding to the cryptal part) along the villus axis, with the activity of individual cells obtained by successive separation, revealed similar values of the percentage quotient derived from the entire activities in these two different methods. This suggests that the presented separation procedure gives rise to isolation of the respective cells from the corresponding areas of the villus. Finally, the isolated cells can be used as a valuable tool for the quantitative analysis of alkaline phosphatase activity along the length of the villus.     

Factors affecting lead capture methods for the fine localization of rat lung acid phosphatase

Synopsis Gomori's lead capture method for acid phosphatase localization was adapted for the electron microscope by Holt & Hicks (1961a). The method gave good results in rat liver, but poor tissue preservation with no reaction product in rat lung, and was, therefore, investigated in order to find the optimum conditions for the ultrastructural localization of rat lung acid phosphatase. The conditions investigated included the use of glutaraldehyde or depolymerized paraformaldehyde as the fixative, with and without dimethylsulphoxide; the effect of freezing the tissue; the pH of the incubation medium; and the use of glycerophosphate, naphthol AS-BI phosphate or -naphthyl phosphate as substrates. Improved preservation of ultrastructure with increased yield of reaction product was obtained by prefixing lung in glutaraldehyde containing 10% dimethylsulphoxide, freezing the tissue and incubating at pH 5.7 with -naphthyl phosphate. Tissue preservation was acceptable and dense deposits of reaction product occurred in lysosomal elements of all the alveolar cells and especially in macrophages. Deposits were also found closely associated with the lamellae of the inclusion bodies of Type II cells.     

Effects of Triton X-100 on acid phosphatases with different substrate specificities

Summary The effect of Triton X-100 on the activities of acid phosphatases from wheat germ, potato and human prostate was tested using -glycerophosphate, p-nitro-phenyl phosphate and naphthol AS BI phosphate as substrates. There was little effect on -glycerophosphatase activity at the concentrations of Triton X-100 tested. However at low concen trations of the detergent there was a stimulation of the activities of p-nitrophenyl phosphatase and naphthol phosphatase which were inhibited with the higher concentrations. Triton X-100 was found to enhance colour production between naphthol AS BI and fast red violet LB.Further evidence is presented confirming the presence of more than one acid phosphatase from each of the sources employed.     

A high-molecular weight complex with acid phosphatase activity in human breast cancer

Summary The presence of a high-molecular weight complex with acid phosphatase activity in the cytosol of human mammary tumors is reported. This complex appeared in the cytosol after tissue homogenization in the presence of dithiotreitol, with or without Triton X-100 and at acidic or neutral pH. Upon gel electrophoresis, this fraction showed only one band of enzyme activity which did not enter the fine pore gel. Lubrol or n-butanol had no apparent effect on this complex, and 8 M urea or 2% sodium dodecyl sulfate did not disaggregate this large molecule. After purification by gel filtration, ammonium sulfate precipitation and ion-exchange chromatography an apparent molecular weight or 10⁶ was measured. It hydrolyzed typical acid phosphatase substrates such as p-NPP and -NP, but also ATP and PPi. Only 44% inhibition was observed with L-(+)tartrate and it was still 40% active after 1 hr incubation at 60 °C. Reduction in the presence of SDS yielded several polypeptide bands. It was also detected in some samples of normal mammary tissues, but not in normal human placenta or liver.Abbreviations AP acid phosphatase - C-AP high-molecular weight complex with acid phosphatase activity - SDS sodium dodecyl sulfate - p-NPP p-nitrophenyl phosphate - -NP -naphthyl phosphate - enzyme code number acid phosphatase or ortophosphoric monoester phosphohydrolase (EC 3.1.3.2)     

Human liver acid phosphatases.

Human liver contains three chromatographically distinct forms of non-specific acid phosphatase (EC 3.1.3.2). Acid phosphatases I, II and III have molecular weights of greater than 200 000, of 107 000, and of 13 400, respectively. Following partial purification, isoenzyme II was obtained as a single activity band, as assessed by activity staining with p-nitrophenyl phosphate and alpha-naphthyl phosphate on polyacrylamide gels run at several pH values. With 50mM p-nitrophenyl phosphate as a substrate, enzymes II and III exhibit plateaus of activity over the pH range 3 - 5 and 3.5 - 6, respectively.Acid phosphatase II is not significantly inhibited by 0.5% formaldehyde. The activity of human liver acid phosphatase II and of human prostatic acid phosphatase towards several substrates is compared. The liver enzyme, is marked contrast to the prostatic enzyme, does not hydrolyze O-phosphoryl choline.     

The association of distinct acid phosphatases with the flagella pocket and surface membrane fractions obtained from bloodstream forms of Trypanosoma rhodesiense

Summary Cell fractionation of bloodstream Trypanosoma rhodesiense, using isopycnic sucrose gradient centrifugation, reveals acid phosphatase activities against a range of substrates to be associated, to varying degrees, with subcellular particle populations identified as derived from flagella pocket membrane and surface membrane. Using these same substrates ( and glycerophosphate, p-nitrophenyl phosphate and glucose-6-phosphate) at least two distinct acid phosphatase activities can be distinguished. One is thermolabile ( 80% inactivated after 30 min. at 60°C), sensitive to tartrate (50% inhibited at 1.8 mM Na tartrate) with a pH optimum 4.5 and appears to exhibit little substrate preference. The other acid phosphatase is relatively heat stable (30% inactivated), insensitive to tartrate (> 5.0% inhibited using 1.8 mM Na tartrate) exhibits a somewhat higher pH optimum ( 6.0) and is more substrate specific (6 × more active toward glucose-6-PO₄ than -glycerophosphate). Further cell fractionation experiments reveal 85% of the tartrate sensitive acid phosphatase to be associated with flagella pocket membrane and to account for 80% of the organisms hydrolytic activity toward -glycerophosphate. The tartrate resistant acid phosphatase however, has a much less exclusive localization being almost equally distributed between surface membrane (40%) and flagella pocket membrane (60%).     

Subcellular distributions and properties of rat testicular acid phosphatases

Synopsis Acid phosphatase activities againstp-nitrophenyl phosphate, -naphthyl phosphate -naphthyl phosphate, naphthol AS-BI phosphate, -glycerophosphate and -glycerophosphate were studied in whole homogenates and subcellular fractions of rat testes. The mitochondrial-lysosomal fraction (the 9000 g sediment) was the most active against all these substrates, but a high specific activity was also present in the soluble fraction (105,000 g supernatant). The effect of various inhibitors and activators onp-nitrophenyl phosphate hydrolysis was different in these fractions. The soluble enzyme was markedly stimulated by Co²⁺, Mg²⁺, Mn²⁺, Ni²⁺ and Zn²⁺. The particulate enzyme was inhibited by sodium fluoride, sodium tartrate and sodium molybdate, whereas the soluble activity was sensitive to Cd²⁺, Cu²⁺ and Sn²⁺ as well as to formaldehyde and glutaraldehyde. The soluble acid phosphatase is mainly localized within the seminiferous tubules. The high sensitivity of the soluble activity to the commonly used fixatives may interfere in the histochemical demonstration of the enzyme.     

Characterization of phosphohydrolase activity in bovine spleen extracts: identification of a bis(p-nitrophenyl)phosphate-hydrolyzing activity (phosphodiesterase IV) which also acts on adenosine triphosphate

Several bovine spleen enzymes with acid pH optima, some of which hydrolyze bis(p-nitrophenyl)phosphate and therefore fit the definition of "phosphodiesterase IV," were partially separated by isoelectric focusing and ion-exchange techniques. The activities were characterized by zymogram analysis with the aid of p-nitrophenyl and 4-methylumbelliferyl phosphate and phosphonate substrates. A number of these enzymes meet the criteria for phosphodiesterase I or other phosphodiesterases. However, the predominant phosphodiesterase I hydrolyzes the bis(p-nitrophenyl)-and 4-methylumbelliferyl phosphates, p-nitrophenyl and 4-methylumbelliferyl phenylphosphonate, and ATP at the beta-gamma bond, but not p-nitrophenyl or 4-methylumbelliferyl 5'-thymidylate (the usual PDE I substrates). These properties, as well as the pH optimum, distinguish the activity from the previously described, alkaline pH optimum PDE I. A second phosphodiesterase hydrolyzes only the phenylphosphonates. Several other activities, less well described, are apparent on zymograms. None of the phosphodiesterases IV was also a phosphodiesterase II (no hydrolysis of 4-methylumbelliferyl 3'-thymidylate).     

Acid hydrolases in HeLa cells: comparison of methods for light microscopy

To distinguish lysosome populations of HeLa cells, acid phosphatase, beta-glucuronidase, arylsulfatase and esterase were demonstrated using various substrates and couplers with different fixations, pHs and inhibitors. The substrates chosen were for acid phosphatase, naphthol AS-BI phosphate with fast red violet LB at pH 4.6; for beta-glucuronidase, naphthol AS-BI beta-D-glucuronide with fast red violet LB at pH 4.4; for arylsulfatase, p-nitrocatechol sulfate, with lead as the capturing ion, at pH 4.8 and 5.6; and for esterase, naphthol AS-D acetate with fast blue BB at pH 6.5. In the azo-dye methods, the coupling was always simultaneous and results were satisfactory with unfixed cells. For optimal demonstration of arylsulfatase, cells were fixed in glutaraldehyde in 0.1 M cacodylate buffer pH 7.2, 2% for 24 hr or 6.25% for 2 hr, and washed for 1-9 days in 0.1 M veronal acetate buffer pH 7.2, 7.5% with respect to sucrose. Two groups of lysosomes were distinguished. One comprised small bodies, probably primary lysosomes, which lay in a cluster near the nucleus. They had quite stable membranes and were mostly acid phosphatase-positive. They sometimes contained beta-glucuronidase or esterase, but rarely arylsulfatase. The other group included all the acid hydrolase-positive bodies scattered throughout the rest of the cytoplasm. They were mostly larger, with more labile membranes, and contained beta-glucuronidase, esterase or arylsulfatase, but rarely acid phosphatase.     

Lectin binding in skeletal muscle. Evaluation of alkaline phosphatase conjugated avidin staining procedures

Summary Cryostat sections from rat gracilis muscles were incubated with different biotinylated lectins: Con A (Concanavilin A), WGA (Wheat germ agglutinin), SBA (soybean agglutinin), GS I and GS II (Griffonia simplicifolia agglutinin), LCA (Lens culinaris agglutinin), PNA (peanut agglutinin) and PSA (Pisum sativum agglutinin). The sections were subsequently treated with alkaline phosphatase conjugated avidin. The lectin binding sites were visualized after incubation in substrate media containing: (1) 5-bromo-4-chloro indoxyl phosphate and Nitro Blue tetrazolium or copper sulphate; (2) naphthol AS-MX phosphate or naphthol AS-BI phosphate and various types of diazonium salts; (3) -naphthylphosphate and Fast Blue BB; (4) -glycerophosphate according to the method of Gomori. The results obtained with the alkaline phosphatase methods were compared with those seen with a streptavidin-horseradish peroxidase procedure. Several chromogen protocols for visualizing alkaline phosphatase activity showed differences in the ability to detect lectin binding sites. A sarcoplasmic reaction was evident for Con A, GS II, WGA, LCA, and PSA after incubation in the indoxyl phosphate medium. Sarcoplasmic reaction for GS II was also noticed after incubation with naphthol AS-MX Fast Blue BB and -glycerophosphate. The latter substrate also gave rise to a sarcoplasmic Con A reaction. With the indoxylphosphate tetrazolium salt method some muscle fibres showed a very strong intracellular reaction after incubation with Con A and GS II while the staining intensity was weak in other fibres. The same muscle fibres were stained with PAS. No sarcoplasmic reactions were observed with either naphthol phosphate media or with the diaminobenzidine peroxidase methods. Further, the staining of the muscle fibre periphery, connective tissue, and capillaries was intensified using the indoxyl method. The indoxylphosphate-tetrazolium salt method seems to be suitable for future investigations of lectin binding sites in muscle sections.     

A reliable method for simultaneous demonstration of two antigens using a novel combination of immunogold-silver staining and immunoenzymatic labeling.

We have developed a reliable and sensitive immunohistochemical staining technique which allows the simultaneous demonstration of two different antigens expressed in or on the same cell (referred to as mixed labeling), together with the evaluation of the general histopathological appearance of the tissue. The staining procedure combines a three-step (streptavidin-biotin) immunogold-silver staining (IGSS) with a three-step immunoenzymatic labeling. For this purpose, we investigated the compatibility of IGSS with various substrates of peroxidase or alkaline phosphatase (AP). Highly reliable and discernible mixed labeling was achieved only after initial labeling with IGSS followed by AP labeling using the substrates naphthol AS-MX phosphate/Fast Blue or naphthol AS-BI phosphate/New Fuchsin, respectively. To ensure utmost specificity, we applied FITC-conjugated mouse monoclonal antibodies and rabbit anti-FITC immunoglobulins visualized by AP-labeled immunoglobulins and the respective substrate in a final step. This novel approach provides an excellent means for demonstration of immunocompetent cells and unequivocal determination of the percentage of specific cell subsets in infiltrated tissue. The advantages of this method, as compared with double immunofluorescence or double immunoenzymatic labeling, were investigated and are discussed.     

Acid Hydrolases in Hela Cells: Comparison of Methods for Light Microscopy

TO distinguish lysosome populations of HeLa cells, acid phosphatase, /8-glu-curonidase, arylsulfatase and esterase were demonstrated using various substrates and couplers with different fixations, pHs and inhibitors. The substrates chosen were for acid phosphatase, naphthol AS-BI phosphate with fast red violet LB at pH 4.6; for β-glucuronidase, naphthol AS-BI β-D-glucuronide with fast red violet LB at pH 4.4; for arylsulfatase, p-nitrocatechol sulfate, with lead as the capturing ion, at pH 4.8 and 5.6; and for esterase, naphthol AS-D acetate with fast blue BB at pH 6.5. In the azo-dye methods, the coupling was always simultaneous and results were satisfactory with unfixed cells. For optimal demonstration of arylsulfatase, cells were fixed in glutaraldehyde in 0.1 M cacodylate buffer pH 7.2, 2% for 24 hr or 6.25% for 2 hr, and washed for 1-9 days in 0.1 M veronal acetate buffer pH 7.2, 7.5% with respect to sucrose. Two groups of lysosomes were distinguished. One comprised small bodies, probably primary lysosomes, which lay in a cluster near the nucleus. They had quite stable membranes and were mostly acid phosphatase-positive. They sometimes contained β-glucuronidase or esterase, but rarely arylsulfatase. The other group included all the acid hydrolase-positive bodies scattered throughout the rest of the cytoplasm. They were mostly larger, with more labile membranes, and contained β-glucuronidase, esterase or arylsulfatase, but rarely acid phosphatase.     

Cytochemical localization of acid phosphatase and trimetaphosphatase activities in Kurloff cells

After stimulation of guinea pigs with estradiol to increase their Kurloff cell number, spleen imprints were prepared in order to detect non-specific acid phosphatase (AcPase) activity by light microscopic cytochemistry using naphthol AS-BI phosphate as substrate and pararosanilin or fast garnet GBC as coupler. For ultracytochemistry, Kurloff cells were prepared from spleens by filtration through a homogeneizer screen followed by repeated centrifugation. AcPase and trimetaphosphatase activities were tested using beta-glycerophosphate, cytidine-5'-monophosphate and inorganic trimetaphosphate as substrates. Significant enzymatic activities were demonstrated with all the substrates used in the cytoplasmic inclusion body of the Kurloff cells.     

Automated histochemical analysis of cell populations in the intact follicle-associated epithelium of the mouse Peyer's patch

Summary A new technique of quantitative histochemistry has been developed to study the cellular composition of the follicle-associated epithelium of the mouse Peyer's patch. This technique involves applying naphthol AS-BI phosphate to the surface of intact tissue where it is hydrolysed by alkaline phosphatase present in the luminal membrane of the epithelial cells. Naphthol AS-BI produced by this reaction is then coupled to Fast Red TR diazonium salt at the site of hydrolysis. M cells present in the epithelium contain little alkaline phosphatase activity and, therefore, remain white. Treatment with Alcian Blue is finally used to label goblet cells. Subsequent quantitative analysis of alkaline phosphatase-rich cells is carried out by scanning microdensitometry. Using this technique it is possible to detect two populations of alkaline phosphatase-containing cells in mice reared in a normal animal house environment.These results are discussed in relation to possible interactions taking place between enteric antigens and the gut-associated lymphoid tissue which could reduce the ability of follicle-associated enterocytes to express alkaline phosphatase.     

A study of acid phosphatase in mouse kidney using naphthol AS/BI phosphate as a substrate

Summary A kinetic study of mouse kidney acid phosphatase has been performed using an application of the histochemical method ofBurstone (1958a, b). The suitability of the use of naphthol AS/BI phosphate as a substrate for biochemical assays of acid phosphatase has been ascertained. However, the rate of inhibition of the enzyme by sodium molybdate and sodium fluoride suggests that naphthol AS/BI phosphate may represent a substrate for an acid phosphatase different from-glycerophosphatase.